CROSS-REFERENCE TO RELATED APPLICATIONS
The present application claims priority to U.S. Provisional Patent Application No. 61/739,645, filed Dec. 19, 2012, titled “INTERFACE PROTECTION DEVICE WITH INTEGRATED SUPPLY CLAMP AND METHOD OF FORMING THE SAME,” the entirety of which is hereby incorporated herein by reference. The present application also claims priority to U.S. Provisional Patent Application No. 61/875,450, filed Sep. 9, 2013, titled “DEVICES FOR MONOLITHIC DATA CONVERSION INTERFACE PROTECTION AND METHODS OF FORMING THE SAME,” the entirety of which is hereby incorporated herein by reference.
This application is related to U.S. application Ser. No. 14/068,566, entitled “SIGNAL IO PROTECTION DEVICES REFERENCED TO SINGLE POWER SUPPLY AND METHODS OF FORMING THE SAME” (Inventors: Javier Alejandro Salcedo and Srivatsan Parthasarathy; the disclosure of which is incorporated herein by reference in its entirety. This application is also related to copending application titled “INTERFACE PROTECTION DEVICE WITH INTEGRATED SUPPLY CLAMP AND METHOD OF FORMING THE SAME,” Ser. No. 13/754,200, filed on Jan. 30, 2013, the disclosure of which is hereby incorporated by reference in its entirety herein.
BACKGROUND
1. Field
Embodiments of the invention relate to electronic systems, and more particularly, to monolithic electrostatic discharge (ESD) protection devices in multi-Gigabits/second communication interface applications.
2. Description of the Related Technology
Certain electronic systems can be exposed to a transient electrical event, or an electrical signal of a relatively short duration having rapidly changing voltage and high power. Transient electrical events can include, for example, electrostatic discharge (ESD) events.
Transient electrical events can damage integrated circuits (ICs) inside an electronic system due to overvoltage conditions and/or high levels of power dissipation over relatively small areas of the ICs. High power dissipation can increase IC temperature, and can lead to numerous problems, such as thin gate oxide punch-through, shallow junction damage, narrow metal damage, and surface charge accumulation.
Moreover, relatively large scale Systems-on-a-Chip (SoCs) for multi-Gigabits/second communication can integrate distributed and multi-level data conversion functionality on an integrated circuit. Such a system can use process technologies such as complementary-metal-oxide-semiconductor (CMOS) technologies that combine a large digital signal processing unit with high speed analog circuits utilizing supply voltages in the range of, for example, about 0.9 V to about 3 V. Large-scale functionality SoCs are particularly prone to fail during manufacturing due to complexity involved in implementing unconventional distributed on-chip protection against electrical overstress without degrading signal integrity. The damage can be caused by overstress such as charged-device-model (CDM) ESD stress conditions, affecting the yield and viability of the reliable system implementation.
There is a need to provide improved protection devices, including protection devices suitable for relatively large scale Systems-on-a-Chip (SoCs) applications.
SUMMARY
In one embodiment, an apparatus is provided. The apparatus includes a substrate, a first semiconductor region of a first doping type in the substrate, a second semiconductor region of a second doping type in the substrate, a third semiconductor region of the first doping type in the substrate, and a fourth semiconductor region of the second doping type in the substrate. The second semiconductor region is positioned between the first and third semiconductor regions, and the third semiconductor region is positioned between the second and fourth semiconductor regions. The apparatus further includes a first diffusion region of the second type in the first semiconductor region, a first gate region adjacent the first semiconductor region, a second diffusion region of the first type in the second semiconductor region, a third diffusion region of the first type in the second semiconductor region, a fourth diffusion region of the second type in the third semiconductor region, a fifth diffusion region of the first type in the fourth semiconductor region, and a second gate region adjacent the fourth semiconductor region. The second diffusion region, the second semiconductor region, the first semiconductor region, and the first diffusion region are configured to operate as a first silicon controlled rectifier (SCR). Additionally, the third diffusion region, the second semiconductor region, the third semiconductor region, and the fourth diffusion region are configured to operate as a second SCR. Furthermore, the fifth diffusion region, the fourth semiconductor region, the third semiconductor region and the fourth diffusion region are configured to operate as a third SCR.
In another embodiment, a method of manufacturing a protection device is provided. The method includes forming a first semiconductor region of a first doping type in a substrate, forming a second semiconductor region of a second doping type in the substrate, forming a third semiconductor region of the first doping type in the substrate, and forming a fourth semiconductor region of the second doping type in the substrate. The second semiconductor region is positioned between the first and third semiconductor regions, and the third semiconductor region is positioned between the second and fourth semiconductor regions. The method further includes forming a first diffusion region of the second type in the first semiconductor region, forming a first gate region adjacent the first semiconductor region, forming a second diffusion region of the first type in the second semiconductor region, forming a third diffusion region of the first type in the second semiconductor region, forming a fourth diffusion region of the second type in the third semiconductor region, forming a fifth diffusion region of the first type in the fourth semiconductor region, and forming a second gate region adjacent the fourth semiconductor region.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic block diagram of one embodiment of an integrated circuit including an interface.
FIG. 2A is a top plan view of a vertically-segmented protection device according to one embodiment.
FIG. 2B is a cross section of the protection device of FIG. 2A taken along the lines 2B-2B, which has been annotated to illustrate one implementation of terminal connectivity.
FIG. 2C is an annotated cross section of the protection device of FIG. 2A taken along the lines 2B-2B.
FIG. 3 is a circuit diagram of the protection device of FIGS. 2A-2C.
FIG. 4 is a cross section of a protection device according to another embodiment.
FIGS. 5A-5C are examples of graphs of current and voltage versus time for various stress conditions of a protection device according to one embodiment.
FIG. 6 is a graph of one example of capacitance versus voltage for a protection device according to one embodiment.
FIG. 7 is a graph of one example of transmission-line pulsing current versus voltage data for a protection device according to one embodiment.
FIG. 8A is a cross section of a protection device according to another embodiment.
FIG. 8B is a cross section of a protection device according to another embodiment.
FIG. 9A is a cross section of a protection device according to another embodiment.
FIG. 9B is a cross section of a protection device according to another embodiment.
FIG. 10A is a cross section of a protection device according to another embodiment.
FIG. 10B is a cross section of a protection device according to another embodiment.
FIG. 11A is a cross section of a protection device according to another embodiment.
FIG. 11B is a cross section of a protection device according to another embodiment.
DETAILED DESCRIPTION OF EMBODIMENTS
The following detailed description of certain embodiments presents various descriptions of specific embodiments of the invention. However, the invention can be embodied in a multitude of different ways as defined and covered by the claims. In this description, reference is made to the drawings where like reference numerals may indicate identical or functionally similar elements.
Terms such as above, below, over and so on as used herein refer to a device orientated as shown in the figures and should be construed accordingly. It should also be appreciated that because regions within a semiconductor device (such as a transistor) are defined by doping different parts of a semiconductor material with differing impurities or differing concentrations of impurities, discrete physical boundaries between different regions may not actually exist in the completed device but instead regions may transition from one to another. Indeed, the higher dopant concentration regions of semiconductor devices are known as diffusion regions because the dopants tend to at least be partially defined by diffusion and thus by their very nature do not have sharp boundaries. Some boundaries as shown in the accompanying figures are of this type and are illustrated as abrupt structures merely for the assistance of the reader. In the embodiments described below, p-type regions can include a semiconductor material with a p-type dopant, such as boron. Further, n-type regions can include a semiconductor material with an n-type dopant, such as phosphorous. Further, gate dielectric can include insulators, such as high k-dielectric. Further, gates can include conductive regions with variable work functions, such as variable work-function metal or polysilicon. A skilled artisan will appreciate various concentrations of dopants, conductive materials and insulating material can be used in regions described below.
Overview of Monolithic Electrostatic Discharge (ESD) Protection Devices for High Speed Interfaces
To help assure that an electronic system is reliable, manufacturers can test the electronic system under defined stress conditions, which can be described by standards set by various organizations, such as the Joint Electronic Device Engineering Council (JEDEC), the International Electrotechnical Commission (IEC), and the International Organization for Standardization (ISO). The standards can cover a wide multitude of transient electrical events as discussed above, including electrostatic discharge (ESD) events.
Electronic circuit reliability is enhanced by providing protection devices to the certain nodes of an IC, such as the IC's pins or pads. The protection devices can maintain the voltage level at the nodes within a predefined safe range by transitioning from a high-impedance state to a low-impedance state when the voltage of the transient signal reaches a trigger voltage. Thereafter, the protection device can shunt at least a portion of the current associated with the transient signal to prevent the voltage of the transient signal from reaching a positive or negative failure voltage that is one of the most common causes of IC damage.
Certain protection schemes can use separate protection devices to protect a signal node, such as an input and/or output signal pin, and the IC's power high and power low supplies. For example, separate protection structures having separate physical layouts can be provided between the signal node and the power high supply, between the signal node and the power low supply, and between the power high and power low supplies.
Monolithic ESD protection devices and methods of forming the same are provided herein. In certain implementations, a protection device includes a first silicon controlled rectifier (SCR) and a first diode for providing protection between a signal node and a power high supply node, a second SCR and a second diode for providing protection between the signal node and a power low supply node, and a third SCR and a third diode for providing protection between the power high supply node and the power low supply node. The SCR and diode structures can be integrated in a common circuit layout, such that certain wells and active regions are shared between structures. Configuring the protection device in this manner can reduce the protection circuit's area relative to a configuration where protection structures between the various nodes are implemented in a separate layout. In one embodiment, the protection device provides in-situ input/output interface protection using a single cell.
The protection devices described herein can be used to enhance design flexibility by eliminating a need for separate protection structures between power high and power low supplies. The protection devices can aid in providing an integrated protection solution for ICs fabricated using a variety of processes, including, for example, sub-28-nm high-k metal-gate CMOS processes.
In certain implementations, a protection device is integrated as part of a circuit interface and synthesized with input/output (IO) circuit components for distributed wafer-level package and in-situ ESD protection. Such protection devices can be used, for example, in system-on-a-chip (SoC) multi-gigabit/second analog-to-digital and/or digital-to-analog converters. For example, the teachings herein can enable protection of interface nodes associated with high speed data rate converters. For instance, in one implementation, the protection device can provide protection for clock signal nodes operating at up to about 10 GHz and/or to provide protection for analog-to-digital converter inputs operating between about 2 GHz and about 5 GHz.
In certain configurations, the protection devices can provide protection to a voltage domain having less than or equal to about 3 V, for instance, 0.9 V. The protection device can have relatively constant input/output (IO) capacitance. For example, in one implementation, the protection device has an IO capacitance in the range of about 340 femtofarads (fF) to about 360 fF, thereby reducing the impacts of signal distortion associated with capacitive mismatch and/or parasitic capacitive loading. Additionally, in certain implementations, by reducing device width, the capacitance can be proportionally reduced in value down to about 50 fF, thereby achieving a value suitable for use in certain analog-to-digital (ADC) applications having lower capacitance specifications and a smaller stress current handling capability. In certain configurations, the protection devices can have relatively low standing leakage, such as a leakage of less than about 10 nanoamperes (nA) at 125 degrees Celsius (C). The protection devices can also have relatively fast activation, such as a turn-on or activation time of less than about 100 picoseconds (ps). The protection devices can include complementary protection structures embedded in the protection device's integrated layout to provide on-chip protection against different ESD stress modes.
FIG. 1 is a schematic block diagram of one embodiment of an integrated circuit 30. The integrated circuit or IC 30 includes a first protection circuit 1 a, a first signal node 2 a (IO−1), a first power low supply node 3 a (VSS1), a first power high supply node 4 a (VDD1), a second power high supply node 4 b (VDD2), a substrate supply node 5 (VSUB), a receiver 6, a resistor 8, and a diode 9.
In certain implementations, the signal node 2 a, the first power low supply node 3 a, the first power high supply node 4 a, and/or the substrate supply node 5 can correspond to bond pads of an integrated circuit (IC). However, other configurations are possible, such as implementations in which the IC uses bumps to provide electrical connectivity external to the IC. For example, the teachings herein are applicable to ball grid array (BGA) chip-scale package (CSP) configurations. Other forms of contacts are also applicable, such as pins and leads.
In one embodiment, the nodes can be fabricated using metal stacks optimized to minimize capacitance. For instance, the IO signal node can be via/plug connected up to a sixth metal interconnect layer (metal layer 6, not shown) at the device level, while the first power low supply node 3 a and the first power high supply node 4 a can be defined at the device level up to a third metal interconnect layer (metal layer 3, not shown), thereby keeping three levels of metal interconnect layers in between the signal and power reference. From the device metallization definition, a well characterized via/plug/metal stack for about optimum current handling capability and low capacitance can be subsequently used to connect to the top metal interconnect layer, from which the different signals can be redistributed by using a redistribution layer (RDL). In certain implementations, the RDL can correspond to a top-most metal layer added used to connect the different system signals to the bumps with relatively small parasitic interaction.
The integrated circuit 30 illustrates one example of an integrated circuit that can include one or more of the protection devices described herein. However, the protection devices can be used in other integrated circuit configurations, including, for example, implementations of integrated circuits using more or fewer protection devices, signal nodes, and/or power high or power low supply nodes.
The illustrated integrated circuit 30 includes multiple power high supply nodes. As shown in FIG. 1, the first power high supply node 4 a is electrically connected to the second power high supply node 4 b using the diode 9. Providing multiple power high supply nodes can be used to enhance noise isolation between different power domains and/or to permit the power supply domains to operate with different electrical potentials or voltages. Additionally coupling the power high supply nodes in this manner can also aid in providing multiple discharge paths during an ESD event. Although FIG. 1 illustrates the integrated circuit 30 as including one power low supply node 3 a, the integrated circuit 30 can include additional power low supply nodes. Thus, the teachings herein are applicable to ICs that include one or more power high supplies and/or one or more power low supplies.
In one embodiment, a voltage difference between the first power high supply node 4 a and the first power low supply node 3 a is less than or equal to about 0.9 V. However, other configurations are possible.
The first protection circuit 1 a can be used to provide transient electrical event protection to the receiver 6 and/or other circuitry of the integrated circuit 30. For example, the first protection circuit 1 a can protect from ESD events received between the first signal node 2 a and the first power low supply node 3 a, between the first signal node 2 a and the first power high supply node 4 a, and/or between the first power low supply node 3 a and the first power high supply node 4 a.
The signal node 2 can correspond to a wide variety of signaling nodes, such as input or receive nodes, clock signal nodes, output or transmit nodes, and/or input/output or bidirectional nodes.
The first protection circuit 1 a includes a first SCR 11 and a first diode 21 electrically connected in parallel between the first power high supply node 4 a and the signal node 2 a. The first protection circuit 1 a further includes a second SCR 12 and a second diode 22 electrically connected in parallel between the signal node 2 a and the first power low supply node 3 b. The first protection circuit 1 a further includes a third SCR 13 and a third diode 23 electrically connected in parallel between the first power high supply node 4 a and the first power low supply node 3 a. The first protection circuit 1 a further includes a fourth diode 24 electrically connected between the substrate supply node 5 and the first power high supply node 4 a.
The first diode 21 can protect against ESD events that cause the voltage of the signal node 2 a to increase relative to the voltage of the first power high supply node 4 a, and the first SCR 11 can protect against ESD events that cause the voltage of the signal node 2 a to decrease relative to the voltage of the first power high supply node 4 a. Additionally, the second diode 22 can protect against ESD events that cause the voltage of the signal node 2 a to decrease relative to the voltage of the first power low supply node 3 a, and the second SCR 12 can protect against ESD events that cause the voltage of the signal node 2 a to increase relative to the voltage of the first power low supply node 3 a. Additionally, the third diode 23 can protect against ESD events that cause the voltage of the first power high supply node 4 a to decrease relative to the voltage of the first power low supply node 3 a, and the third SCR 13 can protect against ESD events that cause the voltage of the first power high supply node 4 a to increase relative to the voltage of the first power low supply node 3 a. As will be described in detail further below, various SCR and diode structures can share wells, diffusion regions, and/or other structures so as to reduce the protection circuit's area relative to a configuration using protection structures implemented in separate circuit layouts.
In the illustrated configuration, the first protection circuit 1 a further includes the fourth diode 24, which can be electrically connected in parallel with the third diode 23. Configuring the first protection circuit 1 a in this manner can increase the current handling capability of the protection device against ESD events received between the first power high supply node 4 a and the first power low supply node 3 a. The fourth diode 24 can also help to provide protection to certain guard well or ring structures. However, other configurations are possible.
In certain configurations, a voltage used to bias the substrate can be coupled to one or more of the integrated circuit's power supply domains. For example, in the configuration shown in FIG. 1, the resistor 8 has been electrically connected between the substrate supply node 5 and the first power low supply node 3 a. However, other configurations are possible, such as implementations in which the substrate supply node 5 is connected in other ways or implementations in which the substrate supply node 5 is omitted in favor of biasing the substrate using the first power low supply node 3 a.
Various embodiments of protection devices that can be used to implement the first protection circuit 1 a will be described below. Although the protection devices have been described in the context of the integrated circuit 30 of FIG. 1, the protection devices can be used in other configurations of integrated circuits.
FIG. 2A is a top plan view of a protection device 40 according to one embodiment. FIG. 2B is a cross section of the protection device 40 of FIG. 2A taken along the lines 2B-2B. FIG. 2C is an annotated cross section of the protection device 40 of FIG. 2A taken along the lines 2B-2B.
The protection device 40 includes a p-well 42, a first n-well 43 a, a second n-well 43 b, first to sixth p-type diffusion or P+ regions 44 a-44 f, first to fourth n-type diffusion or N+ regions 45 a-45 d, first to third n-type metal (NMET) gate regions 46 a-46 c, first and second p-type metal (PMET) gate regions 47 a, 47 b, oxide regions 48, and first to third resist protective oxide (RPO) regions 41 a-41 c. For purposes of clarity, the oxide regions 48, the NMET gate regions 46 a-46 c, the PMET gate regions 47 a, 47 b, and the RPO regions 41 a-41 c have been omitted from the top plan view of FIG. 2A. The illustrated protection device 40 is fabricated in a p-type substrate 49. However, the teachings herein are applicable to other types of substrates. For example, the teachings herein are applicable to configurations using an n-type substrate in which the polarity of the illustrated active and well regions uses the opposite doping type.
As shown in FIG. 2A, the p-well 42 is disposed in the p-type substrate 49, and the first and second n- wells 43 a, 43 b are configured as adjacent islands in the p-well 42. Additionally, the first P+ region 44 a and the first N+ region 45 a are disposed in a first or left region of the p-well 42, with the first N+ region 45 a positioned between the first P+ region 44 a and the first n-well 43 a. Furthermore, the third N+ region 45 c is disposed in a second or central region of the p-well 42. Additionally, the fifth P+ region 44 e is disposed in a third or right region of the p-well 42. The second P+ region 44 b, the second N+ region 45 b, and the third P+ region 44 c are disposed in the first n-well 43 a. The second P+ region 44 b is positioned between the second N+ region 45 b and the left region of the p-well 42. Additionally, the second N+ region 45 b is positioned between the second and third P+ regions 44 b, 44 c. Furthermore, the third P+ region 44 c is positioned between second N+ region 45 b and the central region of the p-well 42. Additionally, the fourth P+ region 44 d and the fourth N+ region 45 d are disposed in the second n-well 43 b, with the fourth P+ region 44 d positioned between the fourth N+ region 45 d and the central region of the p-well 42. The sixth P+ region 44 f has been configured as a ring that surrounds the first and second n- wells 43 a, 43 b, the first to fourth N+ regions 45 a-45 d, and the first to fifth P+ regions 44 a-44 e.
The first NMET gate region 46 a is positioned over the left region of the p-well 42, and extends between the first P+ region 44 a and the first N+ region 45 a. Additionally, the first PMET gate region 47 a is positioned over a boundary between the first n-well 43 a and the left region of the p-well 42, and extends from the second P+ region 44 b toward the first N+ region 45 a. Furthermore, the second NMET gate region 46 b is positioned over a boundary between the first n-well 43 a and the central region of the p-well 42, and extends from the third N+ region 45 c toward the third P+ region 44 c. Additionally, the third NMET gate region 46 c is positioned over a boundary between the second n-well 43 b and the central region of the p-well 42, and extends from the third N+ region 45 c toward the fourth P+ region 44 d. Furthermore, the second PMET gate region 47 b is poisoned over the second n-well 43 b and extends between the fourth P+ region 44 d and the fourth N+ region 45 d.
In certain processes, such as high-k metal gate CMOS processes, metals can be used to implement the gates of n-type metal oxide semiconductor (NMOS) and p-type metal oxide semiconductor (PMOS) transistors. Additionally, the composition and/or processing of the gate metal of PMOS transistors and the gate metal of NMOS transistors can be separately configured to achieve work functions corresponding to suitable threshold voltages for NMOS and PMOS transistors. As used herein, PMET gate regions can correspond to a gate metal structure associated with the process's PMOS transistors and NMET gate regions can correspond to a gate metal structure associated with the process's NMOS transistors.
In the illustrated configuration, the protection device 40 includes gates implemented using metals having different work functions. However, other configurations are possible, such as implementations in which the gates are made out of materials that are not metals, such as polysilicon. In certain implementations, the gate regions include a conductive structure and a dielectric structure such as silicon dioxide or a high-k dielectric, for example, in the range of 10 angstroms to 50 angstroms.
The illustrated protection device 40 includes the oxide regions 48. Formation of the oxide or isolation regions 48 can involve etching trenches in the p-type substrate 49, filling the trenches with a dielectric, such as silicon dioxide (SiO2), and removing the excess dielectric using any suitable method, such as chemical-mechanical planarization. In certain implementations, the oxide regions 48 can be shallow trench regions disposed between certain active regions.
As shown in FIG. 2A, certain, wells, active regions, and gate regions extend in a first or vertical direction. Configuring the device in this manner can aid in controlling the flow of current during activation of the protection device 40 in a second or horizontal direction.
In certain configurations, the protection device 40 can be implemented using a plurality of sub-cell segments or building blocks that are connected together to operate as the protection device. For example, in the configuration of FIGS. 2A-2C, the protection device 40 has been implemented using three sub-cell segments replicated in the vertical direction, which can be connected to one another using interconnect layers and contacts and can be configurable via metal mask-only change. In some configurations, the sub-cells can also be arranged next to each other in the horizontal direction for facilitating metal connectivity in implementations in which horizontally-orientated cells align better with the IC die aspect ratio.
Implementing the protection device using sub-cells can aid in providing enhanced performance by providing a structure having enhanced manufacturing process control relative to a single cell configuration. For example, using multiple sub-cells can reduce part-to-part variation in the protection device associated with fine process features or misalignment within manufacturing constraints. Such variation can affect standing leakage, current handling capability, and/or breakdown characteristics. Using multiple sub-cells can reduce variation relative to a configuration using a single sub-cell, which can have a relatively large amount of manufacturing variation in certain processes. Although the protection device 40 has been illustrated as including three sub-cells, the protection device 40 can include more or fewer sub-cells.
As shown in FIG. 2A, the sixth P+ region 44 f can be implemented as a ring that surrounds N+ regions, P+ regions, and gate regions associated with each of the sub-cells. The sixth P+ region 44 f can operate as a guard ring for reducing the injection of charge from the protection device 40 into the substrate.
In the illustrated configuration, the first RPO region 41 a is disposed over a portion of the first PMET gate region 47 a and over a surface of the left region of the p-well 42 between the first PMET gate region 47 a and the first N+ region 45 a. Additionally, the second RPO region 41 b is disposed over a portion of the second NMET gate region 46 b and over a surface of the first n-well 43 a between the second NMET gate region 46 b and the third P+ region 44 c. Furthermore, the third RPO region 41 c is disposed over a portion of the third NMET gate region 46 c and over a portion of the second n-well 43 b between the third NMET gate region 46 c and the fourth P+ region 44 d. However, other configurations of RPO regions are possible and/or implementations in which all or part of the RPO regions are omitted.
The RPO regions 41 a-41 c can be used to prevent local formation of a silicide layer on a surface of the protection device 40 during processing. A silicide layer can have a relatively low resistance, and thus can have a high current density during an ESD event. In certain instances, blocking the silicide formation can further enhance high stress current handling capability, as high currents through the silicide layer and/or close to the semiconductor surface can lead to device damage, such as silicide melting associated with Joule heating and lower melting point of the silicide formation. Accordingly, using the RPO regions 41 a-41 c to prevent formation of a silicide layer (while silicide is formed on other contact regions) can increase the protection device's robustness during overstress by relatively increasing an amount of current that flows through the protection device's deeper semiconductor regions, such as the protection device's wells and diffusion regions, compared to the absence of the RPO regions.
When the RPO region is omitted, the MOS-formation induces higher standing leakage current in favor of expediting the turn-on speed during stress.
In the illustrated configuration, a separation is provided between an edge of the PMET gate region 47 a and an edge of the first N+ region 45 a. However, other configurations are possible. For example, the PMET gate region 47 a can be extended to eliminate the separation such that PMET gate region 47 a and the first N+ region 45 a abut. Abutting these two regions can expedite the turn-on of the device during high current stress but can allow a higher MOS-induced standing leakage.
In certain implementations herein, the left region of the p-well 42 can be referred to as a first semiconductor region of the protection device 40, the first n-well 43 a can be referred to as a second semiconductor region of the protection device 40, the central region of the p-well 42 can be referred to as a third semiconductor region of the protection device 40, the second n-well 43 b can be referred to as a fourth semiconductor region of the protection device 40, and the right region of the p-well 42 can be referred to as a fifth semiconductor region of the protection device 40. Although the protection device 40 illustrates a configuration in which the first to fifth semiconductor regions are implemented as wells, other configurations are possible. For example, in various embodiments described below with reference to FIGS. 10A-11B, one or more of the wells are omitted in favor of using native regions.
Although FIG. 2A illustrates one possible top or plan view of the protection device 40, other configurations are possible, such as configurations including more or fewer sub-cells and/or configurations including a different arrangements of wells, gates, and/or diffusions regions. For example, in one embodiment, the left, center, and right regions of the p-well 42 are implemented using multiple p-wells.
With reference to FIGS. 2B-2C, the cross-sections of the protection device 40 have been annotated to schematically depict various electrical connections between the protection device 40 and the signal node 2, a power high supply node VDD, a power low supply node VSS, and a substrate supply node VSUB. One implementation of electrical connections between the nodes and the device's active regions and gate regions has been schematically depicted in FIGS. 2B-2C. The illustrated electrical connections can be made, for example, using contact and metal layers, such as those associated with metallization or back-end processing.
In the illustrated configuration, the first NMET gate region 46 a and the second PMET gate region 47 b are electrically floating. The first NMET gate region 46 a and the second PMET gate region 47 b do not operate as gates of metal oxide semiconductor (MOS) transistors in this configuration, since areas of different doping polarities are on opposing sides of the gate regions. However, the first NMET gate region 46 a and the second PMET gate region 47 b have been advantageously used to operate as implant blocking regions to allow more uniform current conduction and faster response during transient stress conditions.
The second and third NMET gate regions 46 b, 46 c and the first PMET gate region 47 a can be associated with MOS transistor structures, as will be described in further detail below with reference to FIG. 3.
The substrate supply node VSUB has been electrically connected to the sixth P+ region 44 f, which in certain implementations can be positioned along an outer perimeter of the protection device 40 to operate as a guard ring. Connecting the substrate supply node VSUB to the sixth P+ region 44 f can reduce carrier injection and/or the risk of latch-up when the protection device is integrated on-chip. In one embodiment, the sixth P+ region 44 f is Kelvin-connected to a power low supply node such as VSS that controls the voltage of the substrate supply node VSUB. For example, the sixth P+ region 44 f can be connected such that a resistance between the sixth P+ region 44 f and the substrate supply node VSUB is greater than a resistance between the p-type substrate 49 and the power low supply node VSS. Although the protection device 40 is illustrated as including both the substrate supply node VSUB and the power low supply node VSS, other configurations are possible, including, for example, implementations in which the substrate supply VSUB is omitted in favor of electrically connecting the sixth P+ region 44 f to the power low supply node VSS.
The protection device 40 of FIG. 2C has been annotated to show certain equivalent circuit devices formed from the illustrated structure, such as a first NPN bipolar transistor 51, a second NPN bipolar transistor 52, a third NPN bipolar transistor 53, a first resistor 81, a second resistor 82, a third resistor 83, a fourth resistor 84, a first PNP bipolar transistor 61, a second PNP bipolar transistor 62, a third PNP bipolar transistor 63, a first diode 71, a second diode 72, a third diode 73, and a fourth diode 74. For clarity, certain circuit devices have been omitted from FIG. 2C, such as certain MOS transistor structures, which will be described below with reference to FIG. 3. The protection device 40 of FIG. 2C has also been illustrated to include the resistor 80, which can be an explicit resistor provided in certain implementations to provide additional resistance between the second N+ region 45 b and the power high supply node VDD.
The resistor 80 can be implemented in any suitable manner, such as by using a resistive material having a geometry selected to achieve the desired resistance. In one embodiment, the resistor 80 has a resistance selected to be in the range of about 100Ω to about 10 kΩ. In certain implementations, the resistor 80 can be implemented using n-type and/or p-type poly resistor structures integrated within the device formation footprint.
The first NPN bipolar transistor 51 includes an emitter associated with the first N+ region 45 a, a base associated with the left region of the p-well 42, and a collector associated with the first n-well 43 a. The second NPN bipolar transistor 52 includes an emitter associated with the third N+ region 45 c, a base associated with the central region of the p-well 42, and a collector associated with the first n-well 43 a. The third NPN bipolar transistor 53 includes an emitter associated with the third N+ region 45 c, a base associated with the central region of the p-well 42, and a collector associated with the second n-well 43 b. The first PNP bipolar transistor 61 includes an emitter associated with the second P+ region 44 b, a base associated with the first n-well 43 a, and a collector associated with the left region of the p-well 42. The second PNP bipolar transistor 62 includes an emitter associated with the third P+ region 44 c, a base associated with the first n-well 43 a, and a collector associated with the central region of the p-well 42. The third PNP bipolar transistor 63 includes an emitter associated with the fourth P+ region 44 d, a base associated with the second n-well 43 b, and a collector associated with the central region of the p-well 42.
The first diode 71 includes a cathode associated with the first N+ region 45 a and an anode associated with the first P+ region 44 a and the left region of the p-well 42. The second diode 72 includes an anode associated with the fourth P+ region 44 d and a cathode associated with the fourth N+ region 45 d and the second n-well 43 b. The third diode 73 includes an anode associated with the fifth P+ region 44 e and the right region of the p-well 42 and a cathode associated with the second n-well 43 b and the fourth N+ region 45 d.
The first and second diodes 71, 72 include a metal gate structure over the diode's p-n junction interface. For example, in the illustrated configuration, an edge of the first NMET gate region 46 a is positioned over a boundary between the first N+ region 45 a and the left region of the p-well 42, and an edge of the second PMET gate region 47 b is positioned over a boundary between the fourth P+ region 44 d and the second n-well 43 b.
Such diodes can be referred to herein as a “gated diode,” which can provide enhanced conductivity relative to certain conventional diode structures. For example, during an ESD event, forward-diode conduction can be closer to the surface of the gated diode relative to a conventional diode structure. Additionally, the anode and cathode regions of the gated diode can be formed closer to each other, thereby decreasing the diode's resistance and minimizing diode forward recovery. Using one or more gated diodes can result in lower voltage overshot during stress conditions.
The first resistor 81 is associated with a resistance of the p-well 42 and the substrate 49 between the first P+ region 44 a and the bases of the second and third NPN bipolar transistors 52, 53. The second resistor 82 is associated with a resistance of the first n-well 43 a between the second N+ region 45 b and the bases of the first and second PNP bipolar transistors 61, 62. The third resistor 83 is associated with a resistance of the first n-well 43 a between the base of the second PNP bipolar transistor 62 and the collector of the second NPN bipolar transistor 52. The fourth resistor 84 is associated with a resistance of the p-well 42 and the substrate 49 between the fifth P+ region 44 e and the bases of the second and third NPN bipolar transistors 52, 53.
FIG. 3 is a circuit diagram 100 of the protection device 40 of FIGS. 2A-2C. The circuit diagram 100 includes the NPN bipolar transistors 51-53, the PNP bipolar transistors 61-63, the diodes 71-74, and the resistors 80-84, which can be as described earlier. The circuit diagram 100 illustrates various connections between the components and the signal node 2, the power high supply VDD, the power low supply VSS, and the substrate supply node VSUB.
The circuit diagram 100 illustrates one implementation of the first protection circuit 1 a of FIG. 1. For example, the first NPN bipolar transistor 51 and the first PNP bipolar transistor 61 can operate as the first SCR 11, the second NPN bipolar transistor 52 and the second PNP bipolar transistor 62 can operate as the second SCR 12, and the third NPN bipolar transistor 53 and the third PNP bipolar transistor 63 can operate as the third SCR 13. Furthermore, the first to fourth diodes 71-74 of FIG. 3 can operate as the first to fourth diodes 21-24, respectively, of FIG. 1. Additional structures of FIG. 1, such as the resistor 8 have been illustrated in FIG. 3.
The circuit diagram 100 further includes first and second NMOS transistors 91, 94, first and second PMOS transistors 92, 93, and first and second standing current conduction blocking regions 95, 96.
With reference to FIGS. 2C and 3, the first NMOS transistor 91 can have a source associated with the first N+ region 45 a, a drain associated with the first n-well 43 a, a gate associated with the first PMET gate region 47 a, and a body associated with the left region of the p-well 42. As shown in FIG. 2C, a spacing or separation has been provided between the first N+ region 45 a and an edge of the first PMET gate region 47 a. The separation can operate to provide the first standing current conduction blocking region 95 between the source of the first NMOS transistor 91 and the signal node 2. During an ESD event, a displacement current can flow through the first standing current conduction blocking region 95 and the first NMOS transistor 91, thereby reducing the device's on-state resistance. Providing the separation can further operate to reduce the static leakage current of the first NMOS transistor 91 relative to a configuration in which the first N+ region 45 a and the edge of the PMET gate region 47 a abut. Additionally, the first NMOS transistor 91 has been implemented using a gate including PMET, which can operate to increase the first NMOS transistor's threshold voltage and to reduce leakage current relative to a configuration using NMET.
The second NMOS transistor 94 includes a source associated with the third N+ region 45 c, a drain associated with the second n-well 43 b, a gate associated with the third NMET gate region 46 c, and a body associated with the central region of the p-well 42. The second NMOS transistor 94 can enhance protection against an ESD event received between the power high supply node VDD and the power low supply node VSS.
The first PMOS transistor 92 includes a source associated with the fourth P+ region 44 d, a drain associated with the central region of the p-well 42, a gate associated with the third NMET gate region 46 c, and a body associated with second n-well 43 b. As shown in FIG. 2C, a separation has been provided between the fourth P+ region 44 d and an edge of the third NMET gate region 46 c. The separation can operate to provide the second standing current conduction blocking region 96 between the source of the first PMOS transistor 92 and the signal node 2. Providing the separation can operate to reduce static leakage current of the first PMOS transistor 92 relative to a configuration in which the fourth P+ region 44 d and the edge of the third NMET gate region 46 c abut. The first PMOS transistor 92 can enhance protection against an ESD event received between the signal node 2 and the power low supply node VSS.
The second PMOS transistor 93 includes a source associated with the second P+ region 44 b, a drain associated with the left region of the p-well 42, a gate associated with the first PMET gate region 47 a, and a body associated with the first n-well 43 a. The second PMOS transistor 93 can enhance protection against an ESD event that decreases the voltage of the power high supply node VDD relative to the first power low supply node VSS.
FIG. 4 is a cross section of a protection device 110 according to another embodiment. The protection device 110 includes an n-well 103 a, first to third p-wells 102 a-102 c, a deep n-well 108, first to third RPO regions 101 a-101 c, first to fifth P+ regions 104 a-104 e, first to sixth N+ regions 105 a-105 f, first and second NMET gate regions 106 a, 106 b, first to third PMET gate regions 107 a-107 c, and oxide regions 48. The protection device 110 is fabricated in the p-type substrate 49.
The protection device 110 of FIG. 4 is similar to the protection device 40 of FIGS. 2A-2C, except that the doping of the wells and diffusion regions have been reversed so as to provide a protection device of a complementary polarity and isolate the different device regions from the substrate. For example, the n-well 103 a of FIG. 4 can correspond to the p-well 42 of FIGS. 2A-2C but with polarity reversed, and the first and second p- wells 102 a, 102 b of FIG. 4 can correspond to the first and second n- wells 43 a, 43 b, respectively, of FIGS. 2A-2C, but with polarity reversed. Similarly, the first to sixth N+ regions 105 a-105 f of FIG. 4 can correspond to the first to sixth P+ regions 44 a-44 f, respectively, of FIGS. 2A-2C, but with polarity reversed Likewise, the first to fourth P+ regions 104 a-104 d of FIG. 4 can correspond to the first to fourth N+ regions 45 a-45 d, respectively, of FIGS. 2A-2C, respectively, but with polarity reversed. Furthermore, the first and second NMET gate regions 106 a, 106 b of FIG. 4 can correspond to the first and second PMET gate regions 47 a, 47 b, respectively, of FIGS. 2A-2C, but with polarity reversed. Additionally, the first to third PMET gate regions 107 a-107 c of FIG. 4 can correspond to the first to third NMET gate regions 46 a-46 c, respectively, of FIGS. 2A-2C, but with polarity reversed. Furthermore, the first to third RPO regions 101 a-101 c of FIG. 4 can correspond to the first to third RPO regions 41 a-41 c, respectively, of FIGS. 2A-2C.
Relative to the protection device 40 of FIGS. 2A-2C, the protection device 110 of FIG. 4 further includes the fifth P+ region 104 e, the third p-well 102 c, and the deep n-well 108. The fifth P+ region 104 e and the third p-well 102 c can be configured to surround a perimeter of the protection device 110, and can operate as a guard ring to reduce carrier injection into the p-type substrate 49 to enhance latch-up robustness. The deep n-well 108 has been positioned beneath the n-well 103 a and the first and second p- wells 102 a, 102 b, and can be used to electrically isolate the first and second p- wells 102 a, 102 b from the p-type substrate 49.
To maintain proper junction biasing, the electrical connections between the protection device 110 of FIG. 4 and the power high and low supply nodes VDD, VSS have been reversed relative to the configuration of FIGS. 2A-2C.
Additional details of the protection device 110 can be similar to those described earlier.
FIGS. 5A-5C are examples of graphs of current and voltage versus time for various stress conditions of a protection device according to one embodiment. The data corresponds to transmission line pulsing (TLP) data for one implementation of the protection device 40 of FIGS. 2A-2C. Although one example of data has been shown, other data is possible, such as data associated with a particular layout implementation and/or process used to fabricate the protection device.
FIG. 5A corresponds to a graph of IO to VSS transient response for a 1 amp very-fast-transmission-line (vftlp) stress condition having about a 300 ps rise time and a pulse width of about 5 ns. FIG. 5A includes a voltage waveform 191 a and a current waveform 191 b. As shown in FIG. 5A, the illustrated configuration has an overshoot voltage between about 4.5 V and 6 V for less than about 65 ps.
FIG. 5B corresponds to a graph of VDD to IO transient response for a stress condition similar to that described above with reference to FIG. 5A. The graph includes a voltage waveform 192 a and a current waveform 192 b. The illustrated configuration has an overshoot voltage between about 4.5 V and 7 V for less than about 65 ps.
FIG. 5C corresponds to a graph of VDD to VSS transient response for a stress condition similar to that described above with reference to FIG. 5A. The graph includes a voltage waveform 192 a and a current waveform 192 b. The illustrated configuration has an overshoot voltage between about 4.5 V and 7 V for less than about 65 ps.
FIG. 6 is a graph 164 of one example of capacitance versus voltage for a protection device according to one embodiment. The data corresponds to capacitance data for one implementation of the protection device 40 of FIGS. 2A-2C with 6 segments/5-μm wide each of them, for a total of 30 μm in width.
The graph 164 is taken for various amounts of voltage difference between power high and power low supply voltages. As shown in FIG. 6, the capacitance can be in the range of amount 340 fF to about 360 fF, including metallization. The relatively small amount of parasitic capacitance can be further reduced by disconnecting segments of the device via metal change. The relatively small amount of parasitic capacitance can result in the protection device having a relatively small impact on signal distortion of signals transmitted or received on the signal node.
Although one example of capacitance data has been shown, capacitance data can vary depending on a variety of factors. For example, the amount of capacitance can depend in part on a size and or number of sub-cells (see the top plan view of FIG. 2A) used to implement the protection device. For example, in one embodiment, a width of each sub-cell can be in the range of about 10 μm to about 40 μm, and a height of each sub-cell can be in the range of about 4 μm to about 8 μm, and an overall capacitance on the signal node can be in the range of about 70 fF to about 400 fF. However, other configurations are possible.
FIG. 7 is a graph of one example of transmission-line pulsing current versus voltage data for a protection device according to one embodiment. The data can correspond to TLP data for one implementation of the protection device 40 of FIGS. 2A-2C. However, other results are possible.
The graph includes a first plot 195 a of the forward-biased diode for IO to VDD stress and a second plot 195 b in response of the SCR—like structure to the IO to VSS stress. The first and second plots 195 a, 195 b correspond to measurements associated with a TLP pulse having about a 600 ps rise time and about a 100 ns width. As shown in FIG. 7, the protection device can have a TLP current handling capability in the range of about 1 A to about 1.5 A and trigger voltage under about 2 V in the IO to VSS stress condition.
FIG. 8A is a cross section of a protection device 200 according to another embodiment. The protection device 200 includes the n-well 103 a, first to third p-wells 102 a-102 c, the deep n-well 108, first and second RPO regions 201 a, 201 b, first to fifth P+ regions 104 a-104 e, first to sixth N+ regions 105 a-105 f, first and second NMET gate regions 206 a, 206 b, first to third PMET gate regions 207 a-207 c, and oxide regions 48. The protection device 110 is fabricated in the p-type substrate 49.
The protection device 200 of FIG. 8A is similar to the protection device 110 of FIG. 4, except that the protection device 200 includes a different arrangement of gate regions and RPO regions.
For example, as shown in FIG. 8A, the first PMET gate region 207 a is positioned over the left region of the n-well 103 a and extends between the first N+ region 105 a and the first P+ region 104 a. Additionally, the second PMET gate region 207 b is positioned over a boundary between the first p-well 102 a and the left region of the n-well 103 a, and extends from the first P+ region 104 a toward the second N+ region 105 b. As shown in FIG. 8A, the first RPO region 201 a is disposed over a portion of the second PMET gate region 207 b and over a surface of the first p-well 102 a between the second PMET gate region 207 b and the second N+ region 105 b. Additionally, the third PMET gate region 207 c is positioned over a boundary between the first p-well 102 a and the central region of the n-well 103 a, and extends between the third N+ region 105 c and the third P+ region 104 c. Furthermore, the first NMET gate region 206 a is positioned over a boundary between the second p-well 102 b and the central region of the n-well 103 a, and extends from the fourth N+ region 105 d toward the third P+ region 104 c. As shown in FIG. 8A, the second RPO region 201 b is disposed over a portion of the first NMET gate region 206 a and over a surface of the central region of the n-well 103 a between the first NMET gate region 206 a and the third P+ region 104 c. Additionally, the second NMET gate region 206 b is positioned over the second p-well 102 b, and extends between the fourth N+ region 105 d and the fourth P+ region 104 d. In the illustrated configuration, the first PMET gate region 207 a and the second NMET gate region 206 b are electrically floating. Additionally, the second PMET gate region 207 b and the third PMET gate region 207 c are electrically connected to the power high supply VDD, and the first NMET gate region 206 a is electrically connected to the power low supply VSS.
The protection device 200 has been annotated to include first and second PMOS transistors 202 a, 202 b and first and second NMOS transistors 203 a, 203 b. The first PMOS transistor 202 a includes a source, drain, gate, and body associated with the first P+ region 104 a, the first p-well 102 a, the second PMET gate region 207 b, and the n-well 103 a, respectively. The first NMOS transistor 203 a includes a source, drain, gate, and body associated with the fourth N+ region 105 d, the central region of the n-well 103 a, the first NMET gate region 206 a, and the second p-well 102 b, respectively. The second PMOS transistor 202 b includes a source, drain, gate, and body associated with the third P+ region 104 c, the first p-well 102 a, the third PMET gate region 207 c, and the central region of the n-well 103 a, respectively. The second NMOS transistor 203 b includes a source, drain, gate, and body associated with the third N+ region 105 c, the central region of the n-well 103 a, the third PMET gate region 207 c, and the first p-well 102 a, respectively.
Although FIG. 8A has been annotated to illustrate certain devices, the protection device 200 includes additional devices, including, for example, bipolar transistors that operate in silicon controlled rectifiers (SCRs) as was described earlier. Such details have been omitted from FIG. 8A for clarity.
The first RPO region 201 a provides a separation between an edge of the second PMET gate region 207 b and the second N+ region 105 b, and can be used to prevent formation of an NMOS transistor having a source, drain, and gate associated with the second N+ region 105 b, the left region of the n-well 103 a, and the second PMET gate region 207 b, respectively. Additionally, the second PMET gate region 207 b is electrically connected to the power high supply VDD, which can operate to turn off the first PMOS transistor 202 a during normal signaling conditions. However, during an ESD event between the signal node 2 and the power low supply node VSS, the first PMOS transistor 202 a can activate to enhance the protection device's current handling capability and/or turn-on speed.
Additionally, the second RPO region 201 b provides a separation between an edge of the first NMET gate region 206 a and the third P+ region 104 c, and can be used to prevent formation of a PMOS transistor having a source, drain, and gate associated with the third P+ region 104 c, the second p-well 102 b, and the first NMET gate region 206 a, respectively. Additionally, the second NMET gate region 206 b is electrically connected to the power low supply VSS, which can operate to turn off the first NMOS transistor 203 a during normal signaling conditions. However, during an ESD event between the signal node 2 and the power high supply node VDD, the first NMOS transistor 203 a can activate to aid in providing ESD protection.
In the illustrated configuration, the second NMOS transistor 203 b and the second PMOS transistor 202 b can turn on and conduct during ESD events received between the power low supply VSS and the power high supply VDD.
FIG. 8B is a cross section of a protection device 210 according to another embodiment.
The protection device 210 of FIG. 8B is similar to the protection device 200 of FIG. 8A, except that the protection device 210 illustrates a configuration including a third RPO region 201 c and in which the third PMET gate region 207 c is electrically connected to the power low supply VSS. As shown in FIG. 8B, the third RPO region 201 c is disposed over a portion of the third PMET gate region 207 c and over a surface of the central region of the n-well 103 a between the third PMET gate region 207 c and the third P+ region 104 c.
Configuring the protection device 210 in this manner can prevent formation of the second PMOS transistor 202 b shown in FIG. 8A, and can reduce leakage current of the second NMOS transistor 203 b during normal signaling conditions. The illustrated configuration can be used, for example, in applications having low standing current specifications between power high and power low supplies. However, configuring the protection device 210 in this manner can also reduce the device's current handling capability and/or turn-on speed for ESD events received between the power low supply VSS and the power high supply VDD. Additional details of the protection device 210 of FIG. 8B can similar to those described earlier.
FIG. 9A is a cross section of a protection device 220 according to another embodiment. The protection device 220 includes first and second n- wells 43 a, 43 b, first to sixth p-type diffusion or P+ regions 44 a-44 f, first to fourth n-type diffusion or N+ regions 45 a-45 d, first and second NMET gate regions 226 a, 226 b, first to third PMET gate regions 227 a-227 c, oxide regions 48, and first and second RPO regions 221 a, 221 b. The illustrated protection device 220 is fabricated in the p-type substrate 49.
The protection device 220 of FIG. 9A is similar to the protection device 40 of FIGS. 2A-2C, except that the protection device 220 includes a different arrangement of gate regions and RPO regions. The arrangement of gate and RPO regions is similar to the arrangement shown in FIG. 8A, but with polarity reversed.
For example, as shown in FIG. 9A, the first NMET gate region 226 a is positioned over the left region of the p-well 42 and extends between the first P+ region 44 a and the first N+ region 45 a. Additionally, the second NMET gate region 226 b is positioned over a boundary between the first n-well 43 a and the left region of the p-well 42, and extends from the first N+ region 45 a toward the second P+ region 44 b. As shown in FIG. 9A, the first RPO region 221 a is disposed over a portion of the second NMET gate region 226 b and over a surface of the first n-well 43 a between the second NMET gate region 226 b and the second P+ region 44 b. Additionally, the first PMET gate region 227 a is positioned over a boundary between the first n-well 43 a and the central region of the p-well 42, and extends between the third P+ region 44 c and the third N+ region 45 c. Furthermore, the second PMET gate region 227 b is positioned over a boundary between the second n-well 43 b and the central region of the p-well 42, and extends from the fourth P+ region 44 d toward the third N+ region 45 c. As shown in FIG. 9A, the second RPO region 221 b is disposed over a portion of the second PMET gate region 227 b and over a surface of the central region of the p-well 42 between the second PMET gate region 227 b and the third N+ region 45 c. Additionally, the third PMET gate region 227 c is positioned over the second n-well 43 b, and extends between the fourth P+ region 44 d and the fourth N+ region 45 d. In the illustrated configuration, the first NMET gate region 226 a and the third PMET gate region 227 c are electrically floating. Additionally, the first PMET gate region 227 a and the second PMET gate region 227 b are electrically connected to the power high supply VDD, and the second NMET gate region 226 b is electrically connected to the power low supply VSS.
Additional details of the protection device 220 can be similar to those described earlier.
FIG. 9B is a cross section of a protection device 230 according to another embodiment. The protection device 230 of FIG. 9B is similar to the protection device 220 of FIG. 9A, except that the protection device 230 illustrates a configuration including a third RPO region 221 c and in which the first PMET gate region 227 a is electrically connected to the power low supply VSS. As shown in FIG. 9B, the third RPO region 221 c is disposed over a portion of the first PMET gate region 227 a and over a surface of the first n-well 43 a between the first PMET gate region 227 a and the third P+ region 44 c.
Additional details of the protection device 230 can be similar to those described earlier.
FIG. 10A is a cross section of a protection device 240 according to another embodiment. The protection device 240 includes the n-well 103 a, first to third p-wells 102 a-102 c, the deep n-well 108, first and second RPO regions 201 a, 201 b, first to fifth P+ regions 104 a-104 e, first to sixth N+ regions 105 a-105 f, first and second NMET gate regions 206 a, 206 b, first to third PMET gate regions 207 a-207 c, oxide regions 48, and first and second n-type native regions 245 a, 245 b. The protection device 240 is fabricated in the p-type substrate 49.
The protection device 240 of FIG. 10A is similar to the protection device 200 of FIG. 8A, except that the protection device 240 includes the first and second n-type native regions 245 a, 245 b.
In certain fabrication processes, a native or NTN implant blocking region can be used to block well implants during fabrication. For example, in one embodiment, the NTN implant blocking region can be used to block implants associated with doping n-wells and p-wells, such as the n-well 103 a and the first to third p-wells 102 a-102 c. Use of the NTN implant blocking region can result in the formation of native regions, which have a doping corresponding to a background doping concentration. For example, in the illustrated configuration, the first and second n-type native regions 245 a, 245 b can have an n-type doping corresponding to a background doping concentration or profile associated with formation of the deep n-well 108. After formation of native regions, the NTN implant blocking region can be removed and may not be present after the protection device is fabricated.
As shown in FIG. 10A, the first N+ region 105 a and the first P+ region 104 a are disposed in the first n-type native region 245 a. Additionally, the first PMET gate region 207 a is positioned over the first n-type native region 245 a between the first N+ region 105 a and the first P+ region 104 a. Furthermore, the second PMET gate region 207 b is positioned over a boundary between the first n-type native region 245 a and the first p-well 102 a, and extends from the first P+ region 104 a toward the second N+ region 105 b. Furthermore, the third P+ region 104 c is disposed in the second n-type native region 245 b. Additionally, the third PMET gate region 207 c is positioned over a boundary between the second n-type native region 245 b and the first p-well 102 a, and extends between the third P+ region 104 c and the third N+ region 105 c. Furthermore, the first NMET gate region 206 a is positioned over a boundary between the second n-type native region 245 b and the second p-well 102 b, and extends from the fourth N+ region 105 d toward the third P+ region 104 c. The second RPO region 201 b includes a first portion over the first NMET gate region 206 a and a second portion over a surface of the second n-type native region 245 b between the third P+ region 104 c and the first NMET gate region 206 a.
Including the first and second n-type native regions 245 a, 245 b in the protection device 240 can reduce a parasitic capacitance of the device relative to a configuration using wells rather than native regions. Additional details of the protection device 240 can be similar to those described earlier.
FIG. 10B is a cross section of a protection device 250 according to another embodiment. The protection device 250 of FIG. 10B is similar to the protection device 240 of FIG. 10A, except that the protection device 250 illustrates a configuration including a third RPO region 201 c and in which the third PMET gate region 207 c is electrically connected to the power low supply VSS. As shown in FIG. 10B, the third RPO region 201 c is disposed over a portion of the third PMET gate region 207 c and over a surface of the second n-type native region 245 b between the third PMET gate region 207 c and the third P+ region 104 c.
Additional details of the protection device 250 can be similar to those described earlier.
FIG. 11A is a cross section of a protection device 260 according to another embodiment. The protection device 260 includes first and second n- wells 43 a, 43 b, first to sixth p-type diffusion or P+ regions 44 a-44 f, first to fourth n-type diffusion or N+ regions 45 a-45 d, first and second NMET gate regions 226 a, 226 b, first to third PMET gate regions 227 a-227 c, oxide regions 48, first and second RPO regions 221 a, 221 b, and first and second p-type native regions 265 a, 265 b. The illustrated protection device 260 is fabricated in the p-type substrate 49.
The protection device 260 of FIG. 11A is similar to the protection device 220 of FIG. 9A, except that the protection device 260 includes the first and second p-type native regions 265 a, 265 b.
As described earlier, in certain fabrication processes, an NTN implant blocking region can be used to block well implants during fabrication. The NTN implant blocking region can be used to block implants associated with doping n-wells and p-wells, such as the p-well 42 first and second n- wells 43 a, 43 b. Use of the NTN implant blocking region can result in the formation of native regions, which have a doping corresponding to a background doping concentration. For example, in the illustrated configuration, the first and second p-type native regions 265 a, 265 b can have a p-type doping corresponding to a background doping concentration or profile associated with doping of the p-type substrate 49. After formation of native regions, the NTN implant blocking region can be removed and may not be present after the protection device is fabricated.
As shown in FIG. 11A, the first P+ region 44 a and the first N+ region 45 a are disposed in the first p-type native region 265 a. Additionally, the first NMET gate region 226 a is positioned over the first p-type native region 265 a between the first P+ region 44 a and the first N+ region 45 a. Furthermore, the second NMET gate region 226 b is positioned over a boundary between the first p-type native region 265 a and the first n-well 43 a, and extends from the first N+ region 45 a toward the second P+ region 44 b. Furthermore, the third N+ region 45 c is disposed in the second p-type native region 265 b. Additionally, the first PMET gate region 227 a is positioned over a boundary between the second p-type native region 265 b and the first n-well 43 a, and extends between the third N+ region 45 c and the third P+ region 44 c. Furthermore, the first PMET gate region 227 a is positioned over a boundary between the second p-type native region 265 b and the second n-well 43 b, and extends from the fourth P+ region 44 d toward the third N+ region 45 c. The second RPO region 221 b includes a first portion over the second PMET gate region 227 b and a second portion over a surface of the second p-type native region 265 b between the third N+ region 45 c and the second PMET gate region 227 b.
Including the first and second p-type native regions 265 a, 265 b in the protection device 260 can reduce a parasitic capacitance of the device relative to a configuration using wells rather than native regions. Additional details of the protection device 260 can be similar to those described earlier.
FIG. 11B is a cross section of a protection device 270 according to another embodiment. The protection device 270 of FIG. 11B is similar to the protection device 260 of FIG. 11A, except that the protection device 270 illustrates a configuration including a third RPO region 221 c and in which the first PMET gate region 227 a is electrically connected to the power low supply VSS. As shown in FIG. 11B, the third RPO region 221 c is disposed over a portion of the first PMET gate region 227 a and over a surface of the second p-type native region 265 b between the first PMET gate region 227 a and the third P+ region 44 c.
Additional details of the protection device 270 can be similar to those described earlier.
Applications
Devices employing the above described protection schemes can be implemented into various electronic devices and interface applications. Examples of the electronic devices can include, but are not limited to, consumer electronic products, parts of the consumer electronic products, electronic test equipment as well as high robustness industrial and automotive applications, among other applications in the semiconductor industry. Examples of the electronic devices can also include circuits of optical networks or other communication networks and circuits for voltage reference and electrical cars battery power management. The electronic products can include, power management integrated circuits for cell phones, base stations, a vehicle engine management controller, a transmission controller, etc. Further, the electronic device can include unfinished products, including those for industrial, medical and automotive applications.
The foregoing description and claims may refer to elements or features as being “connected” or “coupled” together. As used herein, unless expressly stated otherwise, “connected” means that one element/feature is directly or indirectly connected to another element/feature, and not necessarily mechanically. Likewise, unless expressly stated otherwise, “coupled” means that one element/feature is directly or indirectly coupled to another element/feature, and not necessarily mechanically. Thus, although the various schematics shown in the figures depict example arrangements of elements and components, additional intervening elements, devices, features, or components may be present in an actual embodiment (assuming that the functionality of the depicted circuits is not adversely affected).
Although this invention has been described in terms of certain embodiments, other embodiments that are apparent to those of ordinary skill in the art, including embodiments that do not provide all of the features and advantages set forth herein, are also within the scope of this invention. Moreover, the various embodiments described above can be combined to provide further embodiments. In addition, certain features shown in the context of one embodiment can be incorporated into other embodiments as well. Accordingly, the scope of the present invention is defined only by reference to the appended claims.